Optical Tweezers in Studies of Red Blood Cells

Zhu, Ruixue; Avsievich, Tatiana; Попов, А. П.; Meglinski, Igor

doi:10.3390/cells9030545

Cited by 96 publications

(61 citation statements)

References 158 publications

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“…Recently, the active nature of RBC flickering was investigated using active and passive microrheology of a single RBC in a sophisticated four-bead OT configuration [ 21 ]. The advances in OT technology, such as multiple and dynamic optical traps and circular to linear light polarization in OTs, allowed for multiple applications in studies of RBCs, as also shown in two recent reviews [ 22 , 23 ].…”

Section: Introductionmentioning

confidence: 99%

Biomechanics of Ex Vivo-Generated Red Blood Cells Investigated by Optical Tweezers and Digital Holographic Microscopy

Bernecker

Lima

Ciubotaru

et al. 2021

Cells

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Ex vivo-generated red blood cells are a promising resource for future safe blood products, manufactured independently of voluntary blood donations. The physiological process of terminal maturation from spheroid reticulocytes to biconcave erythrocytes has not been accomplished yet. A better biomechanical characterization of cultured red blood cells (cRBCs) will be of utmost interest for manufacturer approval and therapeutic application. Here, we introduce a novel optical tweezer (OT) approach to measure the deformation and elasticity of single cells trapped away from the coverslip. To investigate membrane properties dependent on membrane lipid content, two culture conditions of cRBCs were investigated, cRBCPlasma with plasma and cRBCHPL supplemented with human platelet lysate. Biomechanical characterization of cells under optical forces proves the similar features of native RBCs and cRBCHPL, and different characteristics for cRBCPlasma. To confirm these results, we also applied a second technique, digital holographic microscopy (DHM), for cells laid on the surface. OT and DHM provided related results in terms of cell deformation and membrane fluctuations, allowing a reliable discrimination between cultured and native red blood cells. The two techniques are compared and discussed in terms of application and complementarity.

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Section: Introductionmentioning

confidence: 99%

Biomechanics of Ex Vivo-Generated Red Blood Cells Investigated by Optical Tweezers and Digital Holographic Microscopy

Bernecker

Lima

Ciubotaru

et al. 2021

Cells

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“…Most of the relevant studies have been provided by under in-vitro conditions (Ben-Ami et al, 2003 ; Relevy et al, 2008 ; Barshtein et al, 2018 ; Lee et al, 2018 ; Zaninoni et al, 2018 ; Zhu et al, 2020 ), but Jani et al estimate the erythrocyte mechanical properties in-vivo during capillary plug flow. To characterize the mechanical properties of red blood cells, the authors ( Jani et al ) combined the capabilities of intravascular microscopy with numerical simulation.…”

Section: Methods For Characterization Of Rbcs Flow-affecting Propertimentioning

confidence: 99%

“…Spectrum of in-vitro techniques that can be used for characterization of RBCs flow-affecting properties is very broad. This list includes laser ektacytometry ( Semenov et al ; Lee et al ), laser tweezers (Lee et al, 2018 ; Zhu et al, 2020 ), atomic force microscopy (Steffen et al, 2013 ), microfluidics (Ben-Ami et al, 2003 ; Relevy et al, 2008 ; Guo et al, 2016 ; Barshtein et al, 2018 ; Lee et al, 2018 ; Lim et al, 2018 ). In this Research Topic, Depond et al discuss the usefulness of these methods for the characterization of the RBC deformability for malaria patients.…”

Section: Methods For Characterization Of Rbcs Flow-affecting Propertimentioning

confidence: 99%

Editorial: Red Blood Cell Vascular Adhesion and Deformability

Guizouarn

Barshtein

2020

Front. Physiol.

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“…In recent years, researchers also proposed the optical trapping [ 16 , 17 ] or sorting [ 18 ] through optical waveguides, which offers a new approach for single cell or bacterial study. With the in-depth development of research, the combined application of optical tweezers and other technologies has extended to more new research fields, which effectively promotes the development in the fields of life science, material science, physics, chemistry, medicine, and nanotechnology [ 19 , 20 , 21 ].…”

Section: Introductionmentioning

confidence: 99%

Numerical and Experimental Investigation on the Optical Manipulation from an Axicon Lensed Fiber

et al. 2021

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Here we numerically and experimentally studied the optical trapping on a microsphere from an axicon lensed fiber (ALF). The optical force from the fiber with different tapered lengths and by incident light at different wavelengths is calculated. Numerically, the microsphere can be trapped by the fiber with tapered outline and at a short incident wavelength of 900 nm. While for the fiber with tapered outline , the microsphere can be trapped by the light with longer wavelength of 1100 nm, 1300 nm, or 1500 nm. The optical trapping to a polystyrene microsphere is experimentally demonstrated in a microfluidic channel and the corresponding optical force is derived according to the fluid flow speed. This study can provide a guidance for future tapered fibre design for optical trapping to microspheres.

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Optical Tweezers in Studies of Red Blood Cells

Cited by 96 publications

References 158 publications

Biomechanics of Ex Vivo-Generated Red Blood Cells Investigated by Optical Tweezers and Digital Holographic Microscopy

Biomechanics of Ex Vivo-Generated Red Blood Cells Investigated by Optical Tweezers and Digital Holographic Microscopy

Editorial: Red Blood Cell Vascular Adhesion and Deformability

Numerical and Experimental Investigation on the Optical Manipulation from an Axicon Lensed Fiber

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